Desertification of the Amu Darya River Delta and Vegetation Dynamics in the Conditions of the Aral Sea Crisis

IF 0.6 Q4 ECOLOGY Arid Ecosystems Pub Date : 2023-11-25 DOI:10.1134/S2079096123040108
N. M. Novikova, Zh. V. Kuz’mina, N. K. Mamutov
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These endo–ecogenetic successions are determined by the directed reduction in moisture supply in biotopes and accompanying salinization and evolution of soils. The changes occur in both successional and catastrophic ways. In the northern, undeveloped part of the Amu Darya River delta, the reduction of the sea water surface and a sharp drop in water reserves resulted by the 1990s in the formation of environmental conditions typical for desert landscapes: the climate parameters and their regime became close to desert ones, while the groundwater level fell to a depth of 5–10 m, thus, making groundwaters inaccessible to plant roots. Reconstruction of the reservoir system and flooding of former marine bays contribute to the formation of hydromorphic conditions on local sites. Geobotanical studies commenced in the Amu Darya River delta in 1979 and involved route surveys and surveys of topo–ecological profiles passing through the main deltaic relief elements (levees, their slopes, and interchannel depressions) were repeated in the monitoring mode in 1985, 1993, and 1999. Route surveys performed in 2017 showed that the current vegetation dynamics stage involves the formation of desert plant communities. Black saxaul (<i>Haloxylon aphyllum</i> (Minkw.) Iljin) first discovered in the Muynak district in 1993 is actively spreading in the most part of the undeveloped delta that has turned into a wasteland after the extinction of common reed (<i>Phragmites australis</i> (Cav.) Trin. ex Steud.) communities in the 1970s–1980s. The desert species <i>Krasheninnikovia ceratoides</i> (L.) Gueldenst. that has invaded degrading tugai and sparse arborescent saltwort (<i>Salsola dendroides</i> Pall.) monocoenoses on takyr solonchak soils around the same years formed extensive thickets north of the city of Kungrad. Observations on topo–ecological profiles made it possible to examine individual changes and stages in more detail. On the right bank of the Akdar’ya River that feeds the Mezhdurechenskoe Reservoir, on the Porlytau topo–ecological profile located 3 km southwest of the upland of the same name, over the course of the 40-year observation period, the river washed away a section of the near-channel floodplain and levee 500 m wide and was incised 9 m into the ground following a drop in the erosion base level (i.e., water level in the eastern part of the Greater Sea) by 26 m. Plant communities successions develop slowly. They follow the path of successional replacement of an arboreal Рoplar tugai (<i>Populus ariana</i> + <i>Populus pruinosa</i> + <i>Elaeagnus angustifolia</i>–<i>Mixteherbosa</i> with a shrubby tugai with <i>Tamarix ramosissima</i> Ledeb. ending in a nearby section of the interchannel depression with a catastrophic change: the death of the <i>Halostachys belangeriana</i> (Moq.) Botsch. community. This community was formed in 1985 as a result of soil salinization in the area previously occupied by reeds. In 2017, a slow surface desalination process that began in 1993 due to the illuviation of salts from upper (0–10 cm) horizons to lower ones continued in the soil at all survey points on the profile. For the first time, the desert shrub species <i>Krasheninnikovia ceratoides</i> (L.) Gueldenst. was recorded on the tugai fringe in 2017; over time, this species will probably colonize this entire site characterized by the profile. In the northeastern part of the delta, on the Kunyadarya topo–ecological profile that begins on the right bank of the dry channel of the same name and descends in the southeastern direction to the coastal plain, a degrading <i>Populus diversifolia-Halimodendron halodendron</i> tugai on the levee is being replaced by a tamarisk tugai, which is indicated by the species composition of the community: <i>Populus diversifolia-Tamarix</i> <i>laxa</i> + <i>Halimodendron halodendron + T. ramosissima</i>–<i>Atriplex tatarica</i>. In 2017, black saxaul was first recorded in a community formed by tall well-developed tamarisks and succulent saltworts located further along the profile on the levee slope. The profile enters a coastal solonchak plain with a <i>Halostachys belangeriana</i>–<i>Climacoptera aralensis</i> community. The salinity profiles of soils under all plant communities have a similar feature: the salt content reaches its maximum in the upper part of the profile (0–10 cm); then it sharply decreases in the 10–20-cm horizon and does not change down the profile to a depth of 50 cm. Salinity profiles of soils on two sites occupied by the tugai have the maximum similarity. The uppermost (0–5 cm) horizon is less saline or somewhat washed out from salts compared to the deeper (5–10 cm) horizon featuring the maximum salt content. In the <i>Halostachys belangeriana</i> community, the salt content reaches its maximum (8.28%) in the surface soil horizon (0–5 cm), then it sharply decreases to 2% in the 10–20-cm horizon, and further decreases down the profile to almost 1%. The salinity profile under tamarisk communities differs from other profiles: overall, it is slightly saline and has two maxima: mild surface salinity (0.5% at a depth of 0–5 cm) and medium salinity (0.8%) at a depth of 20–30 cm. Salinity profiles of soils on the Kunyadarya topo–ecological profile indicate progressive salinization of soils with a clearly pronounced surface-accumulative profile under the impact of pulsating secondary hydromorphism in this area provoked by water flows from the Dzhiltyrbas Bay towards the sea that occur on a periodic basis. In 2017, a newly-formed young woody tugai on the bank of an irrigation canal crossing the degrading Yerkin tugai was described. It differs from the degrading tugai forests described earlier in its full-fledged structure (it has three storeys) and in richness of its plant species composition (12 species). Two liana species are present, and renewal of predominant tree species occurs. The soil under the young tugai is alluvial–meadow–tugai (hydromorphic); it is slightly saline (0.36%) only in the near-surface horizon (0–5 cm). Comparison of data collected on topo–ecological profiles with data collected in the course of previous observations made it possible for the first time to conclude that the changes of plant associations in woody tugai communities in the undeveloped part of the delta under the desertification conditions occurs mainly in a successional way; while herbaceous and shrub communities, especially halophilic ones and their variants, are characterized by predominantly catastrophic changes. After their death, long-lasting wastelands are formed on lands previously occupied by such communities where favorable conditions for the introduction of species with different ecology are created. In local hydromorphic conditions with floodplain regimes, the formation and existence of tugai plant communities is possible. The practical significance of the results is that they characterize the diversity of environmental conditions and processes currently occurring in the vegetation and landscapes in the undeveloped part of the Amu Darya River delta and can be applied in resource use and biodiversity conservation practices.</p>","PeriodicalId":44316,"journal":{"name":"Arid Ecosystems","volume":null,"pages":null},"PeriodicalIF":0.6000,"publicationDate":"2023-11-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Arid Ecosystems","FirstCategoryId":"1085","ListUrlMain":"https://link.springer.com/article/10.1134/S2079096123040108","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"ECOLOGY","Score":null,"Total":0}
引用次数: 0

Abstract

This paper discusses the dynamics of ecosystems and their components in connection with the development of the Aral Sea environmental crisis. The theoretical basis of this study was the idea that the vegetation dynamics under the conditions of deltaic landscape desertification represents an anthropogenically-induced natural hologenetic process involving the replacement of vegetation typical for hydromorphic floodplain and reed-bed biotopes with vegetation of semihydromorphic meadow and solonchak biotopes resulting in the formation of zonal vegetation typical for automorphic biotopes. These endo–ecogenetic successions are determined by the directed reduction in moisture supply in biotopes and accompanying salinization and evolution of soils. The changes occur in both successional and catastrophic ways. In the northern, undeveloped part of the Amu Darya River delta, the reduction of the sea water surface and a sharp drop in water reserves resulted by the 1990s in the formation of environmental conditions typical for desert landscapes: the climate parameters and their regime became close to desert ones, while the groundwater level fell to a depth of 5–10 m, thus, making groundwaters inaccessible to plant roots. Reconstruction of the reservoir system and flooding of former marine bays contribute to the formation of hydromorphic conditions on local sites. Geobotanical studies commenced in the Amu Darya River delta in 1979 and involved route surveys and surveys of topo–ecological profiles passing through the main deltaic relief elements (levees, their slopes, and interchannel depressions) were repeated in the monitoring mode in 1985, 1993, and 1999. Route surveys performed in 2017 showed that the current vegetation dynamics stage involves the formation of desert plant communities. Black saxaul (Haloxylon aphyllum (Minkw.) Iljin) first discovered in the Muynak district in 1993 is actively spreading in the most part of the undeveloped delta that has turned into a wasteland after the extinction of common reed (Phragmites australis (Cav.) Trin. ex Steud.) communities in the 1970s–1980s. The desert species Krasheninnikovia ceratoides (L.) Gueldenst. that has invaded degrading tugai and sparse arborescent saltwort (Salsola dendroides Pall.) monocoenoses on takyr solonchak soils around the same years formed extensive thickets north of the city of Kungrad. Observations on topo–ecological profiles made it possible to examine individual changes and stages in more detail. On the right bank of the Akdar’ya River that feeds the Mezhdurechenskoe Reservoir, on the Porlytau topo–ecological profile located 3 km southwest of the upland of the same name, over the course of the 40-year observation period, the river washed away a section of the near-channel floodplain and levee 500 m wide and was incised 9 m into the ground following a drop in the erosion base level (i.e., water level in the eastern part of the Greater Sea) by 26 m. Plant communities successions develop slowly. They follow the path of successional replacement of an arboreal Рoplar tugai (Populus ariana + Populus pruinosa + Elaeagnus angustifoliaMixteherbosa with a shrubby tugai with Tamarix ramosissima Ledeb. ending in a nearby section of the interchannel depression with a catastrophic change: the death of the Halostachys belangeriana (Moq.) Botsch. community. This community was formed in 1985 as a result of soil salinization in the area previously occupied by reeds. In 2017, a slow surface desalination process that began in 1993 due to the illuviation of salts from upper (0–10 cm) horizons to lower ones continued in the soil at all survey points on the profile. For the first time, the desert shrub species Krasheninnikovia ceratoides (L.) Gueldenst. was recorded on the tugai fringe in 2017; over time, this species will probably colonize this entire site characterized by the profile. In the northeastern part of the delta, on the Kunyadarya topo–ecological profile that begins on the right bank of the dry channel of the same name and descends in the southeastern direction to the coastal plain, a degrading Populus diversifolia-Halimodendron halodendron tugai on the levee is being replaced by a tamarisk tugai, which is indicated by the species composition of the community: Populus diversifolia-Tamarix laxa + Halimodendron halodendron + T. ramosissimaAtriplex tatarica. In 2017, black saxaul was first recorded in a community formed by tall well-developed tamarisks and succulent saltworts located further along the profile on the levee slope. The profile enters a coastal solonchak plain with a Halostachys belangerianaClimacoptera aralensis community. The salinity profiles of soils under all plant communities have a similar feature: the salt content reaches its maximum in the upper part of the profile (0–10 cm); then it sharply decreases in the 10–20-cm horizon and does not change down the profile to a depth of 50 cm. Salinity profiles of soils on two sites occupied by the tugai have the maximum similarity. The uppermost (0–5 cm) horizon is less saline or somewhat washed out from salts compared to the deeper (5–10 cm) horizon featuring the maximum salt content. In the Halostachys belangeriana community, the salt content reaches its maximum (8.28%) in the surface soil horizon (0–5 cm), then it sharply decreases to 2% in the 10–20-cm horizon, and further decreases down the profile to almost 1%. The salinity profile under tamarisk communities differs from other profiles: overall, it is slightly saline and has two maxima: mild surface salinity (0.5% at a depth of 0–5 cm) and medium salinity (0.8%) at a depth of 20–30 cm. Salinity profiles of soils on the Kunyadarya topo–ecological profile indicate progressive salinization of soils with a clearly pronounced surface-accumulative profile under the impact of pulsating secondary hydromorphism in this area provoked by water flows from the Dzhiltyrbas Bay towards the sea that occur on a periodic basis. In 2017, a newly-formed young woody tugai on the bank of an irrigation canal crossing the degrading Yerkin tugai was described. It differs from the degrading tugai forests described earlier in its full-fledged structure (it has three storeys) and in richness of its plant species composition (12 species). Two liana species are present, and renewal of predominant tree species occurs. The soil under the young tugai is alluvial–meadow–tugai (hydromorphic); it is slightly saline (0.36%) only in the near-surface horizon (0–5 cm). Comparison of data collected on topo–ecological profiles with data collected in the course of previous observations made it possible for the first time to conclude that the changes of plant associations in woody tugai communities in the undeveloped part of the delta under the desertification conditions occurs mainly in a successional way; while herbaceous and shrub communities, especially halophilic ones and their variants, are characterized by predominantly catastrophic changes. After their death, long-lasting wastelands are formed on lands previously occupied by such communities where favorable conditions for the introduction of species with different ecology are created. In local hydromorphic conditions with floodplain regimes, the formation and existence of tugai plant communities is possible. The practical significance of the results is that they characterize the diversity of environmental conditions and processes currently occurring in the vegetation and landscapes in the undeveloped part of the Amu Darya River delta and can be applied in resource use and biodiversity conservation practices.

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咸海危机条件下阿姆河三角洲沙漠化与植被动态
本文讨论了与咸海环境危机发展有关的生态系统及其组成部分的动态。本研究的理论基础是,三角洲景观沙漠化条件下的植被动态代表了一个人为诱导的自然全成过程,即典型的水形态洪泛平原和芦苇床生物群落被半水形态草甸和土壤草甸生物群落所取代,从而形成典型的自形态生物群落的地带性植被。这些内生态演替是由生物群落中水分供应的定向减少以及随之而来的土壤盐碱化和演变决定的。这些变化既有连续性的,也有灾难性的。在阿姆河三角洲北部欠发达地区,20世纪90年代以来,由于海水表面的减少和水资源储量的急剧下降,形成了典型的沙漠景观环境条件:气候参数及其状态接近沙漠,而地下水位下降至5 ~ 10 m,使地下水无法进入植物根系。水库系统的重建和前海湾的洪水形成了当地的水形态条件。1979年开始在阿姆河三角洲进行地球植物学研究,并在1985年、1993年和1999年以监测模式重复进行了路线调查和通过主要三角洲地形要素(堤坝、斜坡和河道间洼地)的地形生态剖面调查。2017年的路线调查表明,目前的植被动态阶段涉及沙漠植物群落的形成。黑茄(Haloxylon aphyllum)1993年在穆伊纳克地区首次发现的“一真”,在芦苇(芦苇)灭绝后变成荒地的未开发三角洲的大部分地区正在积极蔓延。指标。在20世纪70年代至80年代的社区。荒漠物种Krasheninnikovia ceratoides (L.)Gueldenst。大约在同一时期,入侵了退化的土盖草和稀疏的乔木盐草(Salsola dendroides Pall.)单科植物,在takyr solonchak土壤上形成了广泛的灌木丛。对地形生态剖面的观察使更详细地检查个体变化和阶段成为可能。河的右岸Akdar大家提要Mezhdurechenskoe水库,在Porlytau topo-ecological剖面位于西南3公里的同名的高地,在40年的观察期,河水冲走的那部分near-channel泛滥平原和堤500米宽,下切9米在地上侵蚀基准面下降后(例如,水位在东部的大海洋)26米。植物群落演替发展缓慢。它们遵循的路径是将乔木型土盖(Рoplar Populus ariana + Populus pruinosa + Elaeagnus angustifolia-Mixteherbosa)连续替换为灌木型土盖(ramosissima Ledeb)。最后在河道间洼地附近的一段发生了灾难性的变化:Halostachys belangeriana (Moq.)的死亡。Botsch。社区。这个社区是在1985年形成的,因为以前被芦苇占据的地区土壤盐碱化。2017年,剖面上所有测点的土壤中,由于盐从上层(0-10厘米)到下层的照射,从1993年开始的缓慢地表淡化过程继续进行。荒漠灌木物种卡拉谢尼尼科亚(Krasheninnikovia ceratoides, L.)Gueldenst。于2017年在土盖边缘录制;随着时间的推移,这一物种可能会在这整个地区定居。在东北三角洲的一部分,Kunyadarya topo-ecological概要文件开始的右岸干燥通道相同的名称和海岸平原降落在东南方向,一个可耻的杨树diversifolia-Halimodendron halodendron堤坝上土加以柽柳土加以取代,由社区的物种组成表示:杨树diversifolia-Tamarix laxa + Halimodendron halodendron + t ramosissima-Atriplex tatarica。2017年,黑萨克索尔首次被记录在一个由高大发育良好的红柳和多肉盐沼组成的群落中,这些群落位于堤坝斜坡的轮廓上。剖面进入一个沿海的solonchak平原,有Halostachys belangeriana-Climacoptera aralensis群落。各植物群落土壤盐度剖面具有相似的特征:剖面上部(0 ~ 10 cm)含盐量最大;然后,它在10 - 20厘米的水平面上急剧下降,并且不会改变剖面到50厘米的深度。
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来源期刊
Arid Ecosystems
Arid Ecosystems ECOLOGY-
CiteScore
1.50
自引率
25.00%
发文量
59
期刊介绍: Arid Ecosystems  publishes original scientific research articles on desert and semidesert ecosystems and environment:systematic studies of arid territories: climate changes, water supply of territories, soils as ecological factors of ecosystems state and dynamics in different scales (from local to global);systematic studies of arid ecosystems: composition and structure, diversity, ecology; paleohistory; dynamics under anthropogenic and natural factors impact, including climate changes; studying of bioresources and biodiversity, and development of the mapping methods;arid ecosystems protection: development of the theory and methods of degradation prevention and monitoring; desert ecosystems rehabilitation;problems of desertification: theoretical and practical issues of modern aridization processes under anthropogenic impact and global climate changes.
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